Changes
On November 30, 2024 at 11:52:51 AM UTC,
admin:
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Moved Seawater carbonate chemistry and photophysiology and hemolytic activity of the dinoflagellate Akashiwo sanguinea from organization PANGAEA (Biosphere) to organization PANGAEA (Oceans)
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Removed the following tags from Seawater carbonate chemistry and photophysiology and hemolytic activity of the dinoflagellate Akashiwo sanguinea
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Added the following tags to Seawater carbonate chemistry and photophysiology and hemolytic activity of the dinoflagellate Akashiwo sanguinea
| f | 1 | { | f | 1 | { |
| 2 | "author": "Ou, Guanyong", | 2 | "author": "Ou, Guanyong", | ||
| 3 | "author_email": "", | 3 | "author_email": "", | ||
| 4 | "citation": [], | 4 | "citation": [], | ||
| 5 | "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700", | 5 | "creator_user_id": "17755db4-395a-4b3b-ac09-e8e3484ca700", | ||
| 6 | "doi": "10.1594/PANGAEA.889140", | 6 | "doi": "10.1594/PANGAEA.889140", | ||
| 7 | "doi_date_published": "2017", | 7 | "doi_date_published": "2017", | ||
| 8 | "doi_publisher": "", | 8 | "doi_publisher": "", | ||
| 9 | "doi_status": "True", | 9 | "doi_status": "True", | ||
| 10 | "extra_authors": [ | 10 | "extra_authors": [ | ||
| 11 | { | 11 | { | ||
| 12 | "extra_author": "Wang, Hong", | 12 | "extra_author": "Wang, Hong", | ||
| 13 | "familyName": "Wang", | 13 | "familyName": "Wang", | ||
| 14 | "givenName": "Hong", | 14 | "givenName": "Hong", | ||
| 15 | "orcid": "" | 15 | "orcid": "" | ||
| 16 | }, | 16 | }, | ||
| 17 | { | 17 | { | ||
| 18 | "extra_author": "Si, Ranran", | 18 | "extra_author": "Si, Ranran", | ||
| 19 | "familyName": "Si", | 19 | "familyName": "Si", | ||
| 20 | "givenName": "Ranran", | 20 | "givenName": "Ranran", | ||
| 21 | "orcid": "" | 21 | "orcid": "" | ||
| 22 | }, | 22 | }, | ||
| 23 | { | 23 | { | ||
| 24 | "extra_author": "Guan, WanChun", | 24 | "extra_author": "Guan, WanChun", | ||
| 25 | "familyName": "Guan", | 25 | "familyName": "Guan", | ||
| 26 | "givenName": "WanChun", | 26 | "givenName": "WanChun", | ||
| 27 | "orcid": "0000-0003-0427-9320" | 27 | "orcid": "0000-0003-0427-9320" | ||
| 28 | } | 28 | } | ||
| 29 | ], | 29 | ], | ||
| 30 | "familyName": "Ou", | 30 | "familyName": "Ou", | ||
| 31 | "givenName": "Guanyong", | 31 | "givenName": "Guanyong", | ||
| 32 | "groups": [], | 32 | "groups": [], | ||
| 33 | "id": "e5fe98ff-970e-4552-98fd-70d054e54b43", | 33 | "id": "e5fe98ff-970e-4552-98fd-70d054e54b43", | ||
| 34 | "isopen": false, | 34 | "isopen": false, | ||
| 35 | "license_id": "CC-BY-3.0", | 35 | "license_id": "CC-BY-3.0", | ||
| 36 | "license_title": "CC-BY-3.0", | 36 | "license_title": "CC-BY-3.0", | ||
| 37 | "metadata_created": "2024-11-29T11:46:01.521852", | 37 | "metadata_created": "2024-11-29T11:46:01.521852", | ||
| n | 38 | "metadata_modified": "2024-11-29T11:46:01.521861", | n | 38 | "metadata_modified": "2024-11-30T11:52:50.880909", |
| 39 | "name": "png-doi-10-1594-pangaea-889140", | 39 | "name": "png-doi-10-1594-pangaea-889140", | ||
| 40 | "notes": "Due to global climate change, marine phytoplankton will | 40 | "notes": "Due to global climate change, marine phytoplankton will | ||
| 41 | likely experience low pH (ocean acidification), high temperatures and | 41 | likely experience low pH (ocean acidification), high temperatures and | ||
| 42 | high irradiance in the future. Here, this work report the results of a | 42 | high irradiance in the future. Here, this work report the results of a | ||
| 43 | batch culture experiment conducted to study the interactive effects of | 43 | batch culture experiment conducted to study the interactive effects of | ||
| 44 | elevated CO2, increased temperature and high irradiance on the harmful | 44 | elevated CO2, increased temperature and high irradiance on the harmful | ||
| 45 | dinoflagellate Akashiwo sanguinea, isolated at Dongtou Island, Eastern | 45 | dinoflagellate Akashiwo sanguinea, isolated at Dongtou Island, Eastern | ||
| 46 | China Sea. The A. sanguineacells were acclimated in high CO2 condition | 46 | China Sea. The A. sanguineacells were acclimated in high CO2 condition | ||
| 47 | for about three months before testing the responses of cells to a full | 47 | for about three months before testing the responses of cells to a full | ||
| 48 | factorial matrix experimentation during a 7-day period. This study | 48 | factorial matrix experimentation during a 7-day period. This study | ||
| 49 | measured the variation in physiological parameters and hemolytic | 49 | measured the variation in physiological parameters and hemolytic | ||
| 50 | activity in 8 treatments, representing full factorial combinations of | 50 | activity in 8 treatments, representing full factorial combinations of | ||
| 51 | 2 levels each of exposure to CO2(400 and 1000 \u03bcatm), temperature | 51 | 2 levels each of exposure to CO2(400 and 1000 \u03bcatm), temperature | ||
| 52 | (20 and 28 \u00b0C) and irradiance (50 and 200 \u03bcmol photons | 52 | (20 and 28 \u00b0C) and irradiance (50 and 200 \u03bcmol photons | ||
| 53 | /m**2/s). Sustained growth of A. sanguinea occurred in all treatments, | 53 | /m**2/s). Sustained growth of A. sanguinea occurred in all treatments, | ||
| 54 | but high CO2 (HC) stimulated faster growth than low CO2 (LC). The | 54 | but high CO2 (HC) stimulated faster growth than low CO2 (LC). The | ||
| 55 | pigments (chlorophyll a and carotenoid) decreased in all HC | 55 | pigments (chlorophyll a and carotenoid) decreased in all HC | ||
| 56 | treatments. The quantum yield (Fv/Fm) declined slightly in all | 56 | treatments. The quantum yield (Fv/Fm) declined slightly in all | ||
| 57 | high-temperature (HT) treatments. High irradiance (HL) induced the | 57 | high-temperature (HT) treatments. High irradiance (HL) induced the | ||
| 58 | accumulation of ultraviolet-absorbing compounds (UVabc) irrespective | 58 | accumulation of ultraviolet-absorbing compounds (UVabc) irrespective | ||
| 59 | of temperature and CO2. The hemolytic activity in the LC treatments, | 59 | of temperature and CO2. The hemolytic activity in the LC treatments, | ||
| 60 | however, declined when exposed to HT and HL, but HC alleviated the | 60 | however, declined when exposed to HT and HL, but HC alleviated the | ||
| 61 | adverse effects of HT and HL on hemolytic activity. All HC and HL | 61 | adverse effects of HT and HL on hemolytic activity. All HC and HL | ||
| 62 | conditions and the combinations of high temperature*high light (HTHL) | 62 | conditions and the combinations of high temperature*high light (HTHL) | ||
| 63 | and high CO2*high temperature*high light (HCHTHL) positively affected | 63 | and high CO2*high temperature*high light (HCHTHL) positively affected | ||
| 64 | the growth in comparison to the low CO2*low temperature*low light | 64 | the growth in comparison to the low CO2*low temperature*low light | ||
| 65 | (LCLTLL) treatment. High temperature (HT), high light (HL) and a | 65 | (LCLTLL) treatment. High temperature (HT), high light (HL) and a | ||
| 66 | combination of HT*HL, however, negatively impacted hemolytic activity. | 66 | combination of HT*HL, however, negatively impacted hemolytic activity. | ||
| 67 | CO2 was the main factor that affected the growth and hemolytic | 67 | CO2 was the main factor that affected the growth and hemolytic | ||
| 68 | activity. There were no significant interactive effects of | 68 | activity. There were no significant interactive effects of | ||
| 69 | CO2*temperature*irradiance on growth, pigment, Fv/Fm or hemolytic | 69 | CO2*temperature*irradiance on growth, pigment, Fv/Fm or hemolytic | ||
| 70 | activity, but there were effects on Pm, \u03b1, and Ek. If these | 70 | activity, but there were effects on Pm, \u03b1, and Ek. If these | ||
| 71 | results are extrapolated to the natural environment, it can be | 71 | results are extrapolated to the natural environment, it can be | ||
| 72 | hypothesized that A. sanguinea cells will benefit from the combination | 72 | hypothesized that A. sanguinea cells will benefit from the combination | ||
| 73 | of ocean acidification, warming, and high irradiance that are likely | 73 | of ocean acidification, warming, and high irradiance that are likely | ||
| 74 | to occur under future climate change. It is assumed that faster growth | 74 | to occur under future climate change. It is assumed that faster growth | ||
| 75 | and higher hemolytic activity and UVabc of this species will occur | 75 | and higher hemolytic activity and UVabc of this species will occur | ||
| 76 | under future conditions compared with those the current CO2 (400 | 76 | under future conditions compared with those the current CO2 (400 | ||
| 77 | \u03bcatm) and temperature (20 \u00b0C) conditions.", | 77 | \u03bcatm) and temperature (20 \u00b0C) conditions.", | ||
| 78 | "num_resources": 0, | 78 | "num_resources": 0, | ||
| n | 79 | "num_tags": 17, | n | 79 | "num_tags": 22, |
| 80 | "orcid": "", | 80 | "orcid": "", | ||
| 81 | "organization": { | 81 | "organization": { | ||
| 82 | "approval_status": "approved", | 82 | "approval_status": "approved", | ||
| n | 83 | "created": "2024-11-29T11:32:00.143130", | n | 83 | "created": "2024-11-30T11:33:58.986659", |
| 84 | "description": "PANGAEA (Data Publisher for Earth & Environmental | 84 | "description": "PANGAEA (Data Publisher for Earth & Environmental | ||
| 85 | Science): The information system PANGAEA is operated as an Open Access | 85 | Science): The information system PANGAEA is operated as an Open Access | ||
| 86 | library aimed at archiving, publishing and distributing georeferenced | 86 | library aimed at archiving, publishing and distributing georeferenced | ||
| 87 | data from earth system research. PANGAEA guarantees long-term | 87 | data from earth system research. PANGAEA guarantees long-term | ||
| 88 | availability (greater than 10 years) of its content. PANGAEA is open | 88 | availability (greater than 10 years) of its content. PANGAEA is open | ||
| 89 | to any project, institution, or individual scientist to use or to | 89 | to any project, institution, or individual scientist to use or to | ||
| 90 | archive and publish data. PANGAEA focuses on georeferenced | 90 | archive and publish data. PANGAEA focuses on georeferenced | ||
| 91 | observational data, experimental data, and models/simulations. | 91 | observational data, experimental data, and models/simulations. | ||
| 92 | Citability, comprehensive metadata descriptions, interoperability of | 92 | Citability, comprehensive metadata descriptions, interoperability of | ||
| 93 | data and metadata, a high degree of structural and semantic | 93 | data and metadata, a high degree of structural and semantic | ||
| 94 | harmonization of the data inventory as well as the commitment of the | 94 | harmonization of the data inventory as well as the commitment of the | ||
| 95 | hosting institutions ensures FAIRness of archived data.", | 95 | hosting institutions ensures FAIRness of archived data.", | ||
| n | 96 | "id": "3226ef9c-20d1-43fd-ba8f-fa35c8c9fb5d", | n | 96 | "id": "ce65c98e-83d7-4b4f-9db3-99759a987d6c", |
| 97 | "image_url": "pangaea_topicbiosphere.png", | 97 | "image_url": "pangaea_topicoceans.png", | ||
| 98 | "is_organization": true, | 98 | "is_organization": true, | ||
| n | 99 | "name": "pangaea_biosphere", | n | 99 | "name": "pangaea_oceans", |
| 100 | "state": "active", | 100 | "state": "active", | ||
| n | 101 | "title": "PANGAEA (Biosphere)", | n | 101 | "title": "PANGAEA (Oceans)", |
| 102 | "type": "organization" | 102 | "type": "organization" | ||
| 103 | }, | 103 | }, | ||
| n | 104 | "owner_org": "3226ef9c-20d1-43fd-ba8f-fa35c8c9fb5d", | n | 104 | "owner_org": "ce65c98e-83d7-4b4f-9db3-99759a987d6c", |
| 105 | "private": false, | 105 | "private": false, | ||
| 106 | "publication_year": "2017", | 106 | "publication_year": "2017", | ||
| 107 | "related_identifiers": [ | 107 | "related_identifiers": [ | ||
| 108 | { | 108 | { | ||
| 109 | "authors": "Ou Guanyong,Wang Hong,Si Ranran,Guan WanChun", | 109 | "authors": "Ou Guanyong,Wang Hong,Si Ranran,Guan WanChun", | ||
| 110 | "email_authors": ",,,gwc@wmu.edu.cn", | 110 | "email_authors": ",,,gwc@wmu.edu.cn", | ||
| 111 | "identifier": "https://doi.org/10.1016/j.hal.2017.08.003", | 111 | "identifier": "https://doi.org/10.1016/j.hal.2017.08.003", | ||
| 112 | "identifier_type": "DOI", | 112 | "identifier_type": "DOI", | ||
| 113 | "orcid_authors": ",,,0000-0003-0427-9320", | 113 | "orcid_authors": ",,,0000-0003-0427-9320", | ||
| 114 | "relation_type": "IsSupplementTo", | 114 | "relation_type": "IsSupplementTo", | ||
| 115 | "source": "Harmful Algae", | 115 | "source": "Harmful Algae", | ||
| 116 | "title": "The dinoflagellate Akashiwo sanguinea will benefit | 116 | "title": "The dinoflagellate Akashiwo sanguinea will benefit | ||
| 117 | from future climate change: The interactive effects of ocean | 117 | from future climate change: The interactive effects of ocean | ||
| 118 | acidification, warming and high irradiance on photophysiology and | 118 | acidification, warming and high irradiance on photophysiology and | ||
| 119 | hemolytic activity", | 119 | hemolytic activity", | ||
| 120 | "year": "2017" | 120 | "year": "2017" | ||
| 121 | }, | 121 | }, | ||
| 122 | { | 122 | { | ||
| 123 | "authors": "Gattuso Jean-Pierre,Epitalon Jean-Marie,Lavigne | 123 | "authors": "Gattuso Jean-Pierre,Epitalon Jean-Marie,Lavigne | ||
| 124 | H\u00e9lo\u00efse,Orr James C,Gentili Bernard,Proye | 124 | H\u00e9lo\u00efse,Orr James C,Gentili Bernard,Proye | ||
| 125 | Aur\u00e9lien,Soetaert Karline,Rae James", | 125 | Aur\u00e9lien,Soetaert Karline,Rae James", | ||
| 126 | "email_authors": | 126 | "email_authors": | ||
| 127 | ,j.orr@iaea.org,bernard.gentili@orange.fr,,karline.soetaert@nioz.nl,", | 127 | ,j.orr@iaea.org,bernard.gentili@orange.fr,,karline.soetaert@nioz.nl,", | ||
| 128 | "identifier": "https://cran.r-project.org/package=seacarb", | 128 | "identifier": "https://cran.r-project.org/package=seacarb", | ||
| 129 | "identifier_type": "DOI", | 129 | "identifier_type": "DOI", | ||
| 130 | "orcid_authors": | 130 | "orcid_authors": | ||
| 131 | 4114,,,0000-0002-8707-7080,,,0000-0003-4603-7100,0000-0003-3904-2526", | 131 | 4114,,,0000-0002-8707-7080,,,0000-0003-4603-7100,0000-0003-3904-2526", | ||
| 132 | "relation_type": "References", | 132 | "relation_type": "References", | ||
| 133 | "source": "", | 133 | "source": "", | ||
| 134 | "title": "seacarb: seawater carbonate chemistry with R. R | 134 | "title": "seacarb: seawater carbonate chemistry with R. R | ||
| 135 | package version 3.1", | 135 | package version 3.1", | ||
| 136 | "year": "2016" | 136 | "year": "2016" | ||
| 137 | } | 137 | } | ||
| 138 | ], | 138 | ], | ||
| 139 | "relationships_as_object": [], | 139 | "relationships_as_object": [], | ||
| 140 | "relationships_as_subject": [], | 140 | "relationships_as_subject": [], | ||
| 141 | "repository_name": "PANGAEA (Data Publisher for Earth & | 141 | "repository_name": "PANGAEA (Data Publisher for Earth & | ||
| 142 | Environmental Science)", | 142 | Environmental Science)", | ||
| 143 | "resource_type": "text/tab-separated-values - filename: | 143 | "resource_type": "text/tab-separated-values - filename: | ||
| 144 | Ou-etal_2017_HA", | 144 | Ou-etal_2017_HA", | ||
| 145 | "resources": [], | 145 | "resources": [], | ||
| 146 | "source_metadata_created": "2017", | 146 | "source_metadata_created": "2017", | ||
| 147 | "source_metadata_modified": "", | 147 | "source_metadata_modified": "", | ||
| 148 | "state": "active", | 148 | "state": "active", | ||
| 149 | "subject_areas": [ | 149 | "subject_areas": [ | ||
| 150 | { | 150 | { | ||
| 151 | "subject_area_additional": "", | 151 | "subject_area_additional": "", | ||
| 152 | "subject_area_name": "BiologicalClassification" | 152 | "subject_area_name": "BiologicalClassification" | ||
| 153 | }, | 153 | }, | ||
| 154 | { | 154 | { | ||
| 155 | "subject_area_additional": "", | 155 | "subject_area_additional": "", | ||
| 156 | "subject_area_name": "Biosphere" | 156 | "subject_area_name": "Biosphere" | ||
| 157 | }, | 157 | }, | ||
| 158 | { | 158 | { | ||
| 159 | "subject_area_additional": "", | 159 | "subject_area_additional": "", | ||
| 160 | "subject_area_name": "Chemistry" | 160 | "subject_area_name": "Chemistry" | ||
| 161 | }, | 161 | }, | ||
| 162 | { | 162 | { | ||
| 163 | "subject_area_additional": "", | 163 | "subject_area_additional": "", | ||
| 164 | "subject_area_name": "Oceans" | 164 | "subject_area_name": "Oceans" | ||
| 165 | } | 165 | } | ||
| 166 | ], | 166 | ], | ||
| 167 | "tags": [ | 167 | "tags": [ | ||
| 168 | { | 168 | { | ||
| n | n | 169 | "display_name": "Abundance", | ||
| 170 | "id": "b6432d44-0a46-478c-8d9a-e9f79213a6a2", | ||||
| 171 | "name": "Abundance", | ||||
| 172 | "state": "active", | ||||
| 173 | "vocabulary_id": null | ||||
| 174 | }, | ||||
| 175 | { | ||||
| 169 | "display_name": "Akashiwo sanguinea", | 176 | "display_name": "Akashiwo sanguinea", | ||
| 170 | "id": "d7fb3cf4-ff94-4635-a36e-c46b76935d7d", | 177 | "id": "d7fb3cf4-ff94-4635-a36e-c46b76935d7d", | ||
| 171 | "name": "Akashiwo sanguinea", | 178 | "name": "Akashiwo sanguinea", | ||
| 172 | "state": "active", | 179 | "state": "active", | ||
| 173 | "vocabulary_id": null | 180 | "vocabulary_id": null | ||
| 174 | }, | 181 | }, | ||
| 175 | { | 182 | { | ||
| n | 176 | "display_name": "Biomass-Abundance-Elemental composition", | n | 183 | "display_name": "Aquaria 20 L", |
| 177 | "id": "5a237d59-e5be-4850-af81-78df25db3959", | 184 | "id": "62c412c1-2294-406a-ad79-183330400def", | ||
| 178 | "name": "Biomass-Abundance-Elemental composition", | 185 | "name": "Aquaria 20 L", | ||
| 179 | "state": "active", | 186 | "state": "active", | ||
| 180 | "vocabulary_id": null | 187 | "vocabulary_id": null | ||
| 181 | }, | 188 | }, | ||
| 182 | { | 189 | { | ||
| n | n | 190 | "display_name": "Biomass", | ||
| 191 | "id": "1d36ab17-1789-476f-b35f-447f5acdc2ac", | ||||
| 192 | "name": "Biomass", | ||||
| 193 | "state": "active", | ||||
| 194 | "vocabulary_id": null | ||||
| 195 | }, | ||||
| 196 | { | ||||
| 183 | "display_name": "Bottles or small containers-Aquaria 20 L", | 197 | "display_name": "Bottles or small containers", | ||
| 184 | "id": "be154617-73a3-4ed4-b54f-69e22323c12a", | 198 | "id": "ba227243-af91-4efc-8086-790112e90e09", | ||
| 185 | "name": "Bottles or small containers-Aquaria 20 L", | 199 | "name": "Bottles or small containers", | ||
| 186 | "state": "active", | 200 | "state": "active", | ||
| 187 | "vocabulary_id": null | 201 | "vocabulary_id": null | ||
| 188 | }, | 202 | }, | ||
| 189 | { | 203 | { | ||
| 190 | "display_name": "Chromista", | 204 | "display_name": "Chromista", | ||
| 191 | "id": "36ecf721-e11a-4662-8783-da539c625d5c", | 205 | "id": "36ecf721-e11a-4662-8783-da539c625d5c", | ||
| 192 | "name": "Chromista", | 206 | "name": "Chromista", | ||
| 193 | "state": "active", | 207 | "state": "active", | ||
| 194 | "vocabulary_id": null | 208 | "vocabulary_id": null | ||
| 195 | }, | 209 | }, | ||
| 196 | { | 210 | { | ||
| 197 | "display_name": "Coast and continental shelf", | 211 | "display_name": "Coast and continental shelf", | ||
| 198 | "id": "58eb1929-34b5-4fd9-ac44-824f0e51de40", | 212 | "id": "58eb1929-34b5-4fd9-ac44-824f0e51de40", | ||
| 199 | "name": "Coast and continental shelf", | 213 | "name": "Coast and continental shelf", | ||
| 200 | "state": "active", | 214 | "state": "active", | ||
| 201 | "vocabulary_id": null | 215 | "vocabulary_id": null | ||
| 202 | }, | 216 | }, | ||
| 203 | { | 217 | { | ||
| n | n | 218 | "display_name": "Elemental composition", | ||
| 219 | "id": "7e17866a-7d27-4b2b-92f9-8c3ab3557a5c", | ||||
| 220 | "name": "Elemental composition", | ||||
| 221 | "state": "active", | ||||
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| 223 | }, | ||||
| 224 | { | ||||
| 204 | "display_name": "Growth-Morphology", | 225 | "display_name": "Growth", | ||
| 205 | "id": "b00c4eac-980d-42b2-bae9-0aa1b212cf54", | 226 | "id": "898cbb0c-ff61-4ca3-9e35-0ef6fbb8eb98", | ||
| 206 | "name": "Growth-Morphology", | 227 | "name": "Growth", | ||
| 207 | "state": "active", | 228 | "state": "active", | ||
| 208 | "vocabulary_id": null | 229 | "vocabulary_id": null | ||
| 209 | }, | 230 | }, | ||
| 210 | { | 231 | { | ||
| 211 | "display_name": "Laboratory experiment", | 232 | "display_name": "Laboratory experiment", | ||
| 212 | "id": "c6c00754-c769-4932-a517-bff2c9512884", | 233 | "id": "c6c00754-c769-4932-a517-bff2c9512884", | ||
| 213 | "name": "Laboratory experiment", | 234 | "name": "Laboratory experiment", | ||
| 214 | "state": "active", | 235 | "state": "active", | ||
| 215 | "vocabulary_id": null | 236 | "vocabulary_id": null | ||
| 216 | }, | 237 | }, | ||
| 217 | { | 238 | { | ||
| 218 | "display_name": "Light", | 239 | "display_name": "Light", | ||
| 219 | "id": "9ac4a69a-37ab-4e4a-9d78-5108602c751e", | 240 | "id": "9ac4a69a-37ab-4e4a-9d78-5108602c751e", | ||
| 220 | "name": "Light", | 241 | "name": "Light", | ||
| 221 | "state": "active", | 242 | "state": "active", | ||
| 222 | "vocabulary_id": null | 243 | "vocabulary_id": null | ||
| 223 | }, | 244 | }, | ||
| 224 | { | 245 | { | ||
| n | n | 246 | "display_name": "Morphology", | ||
| 247 | "id": "2345107d-a1a2-43c1-8b38-d670ea499006", | ||||
| 248 | "name": "Morphology", | ||||
| 249 | "state": "active", | ||||
| 250 | "vocabulary_id": null | ||||
| 251 | }, | ||||
| 252 | { | ||||
| 225 | "display_name": "Myzozoa", | 253 | "display_name": "Myzozoa", | ||
| 226 | "id": "74f5d8f7-98f9-4d59-9be4-4f2460f206e4", | 254 | "id": "74f5d8f7-98f9-4d59-9be4-4f2460f206e4", | ||
| 227 | "name": "Myzozoa", | 255 | "name": "Myzozoa", | ||
| 228 | "state": "active", | 256 | "state": "active", | ||
| 229 | "vocabulary_id": null | 257 | "vocabulary_id": null | ||
| 230 | }, | 258 | }, | ||
| 231 | { | 259 | { | ||
| 232 | "display_name": "North Pacific", | 260 | "display_name": "North Pacific", | ||
| 233 | "id": "efbdbaff-aa72-4a57-8e03-e9f84253d644", | 261 | "id": "efbdbaff-aa72-4a57-8e03-e9f84253d644", | ||
| 234 | "name": "North Pacific", | 262 | "name": "North Pacific", | ||
| 235 | "state": "active", | 263 | "state": "active", | ||
| 236 | "vocabulary_id": null | 264 | "vocabulary_id": null | ||
| 237 | }, | 265 | }, | ||
| 238 | { | 266 | { | ||
| 239 | "display_name": "Other studied parameter or process", | 267 | "display_name": "Other studied parameter or process", | ||
| 240 | "id": "4dbbc15c-38d9-458f-b39a-60a698197ff3", | 268 | "id": "4dbbc15c-38d9-458f-b39a-60a698197ff3", | ||
| 241 | "name": "Other studied parameter or process", | 269 | "name": "Other studied parameter or process", | ||
| 242 | "state": "active", | 270 | "state": "active", | ||
| 243 | "vocabulary_id": null | 271 | "vocabulary_id": null | ||
| 244 | }, | 272 | }, | ||
| 245 | { | 273 | { | ||
| 246 | "display_name": "Pelagos", | 274 | "display_name": "Pelagos", | ||
| 247 | "id": "012f5b69-4e75-4f54-8ac4-8bf192cafaa2", | 275 | "id": "012f5b69-4e75-4f54-8ac4-8bf192cafaa2", | ||
| 248 | "name": "Pelagos", | 276 | "name": "Pelagos", | ||
| 249 | "state": "active", | 277 | "state": "active", | ||
| 250 | "vocabulary_id": null | 278 | "vocabulary_id": null | ||
| 251 | }, | 279 | }, | ||
| 252 | { | 280 | { | ||
| n | n | 281 | "display_name": "Photosynthesis", | ||
| 282 | "id": "ab256517-eb7b-4eed-ad52-64a0ee98fe87", | ||||
| 283 | "name": "Photosynthesis", | ||||
| 284 | "state": "active", | ||||
| 285 | "vocabulary_id": null | ||||
| 286 | }, | ||||
| 287 | { | ||||
| 253 | "display_name": "Phytoplankton", | 288 | "display_name": "Phytoplankton", | ||
| 254 | "id": "9c357867-c046-43fa-ad3e-39f612d5622b", | 289 | "id": "9c357867-c046-43fa-ad3e-39f612d5622b", | ||
| 255 | "name": "Phytoplankton", | 290 | "name": "Phytoplankton", | ||
| 256 | "state": "active", | 291 | "state": "active", | ||
| 257 | "vocabulary_id": null | 292 | "vocabulary_id": null | ||
| 258 | }, | 293 | }, | ||
| 259 | { | 294 | { | ||
| t | 260 | "display_name": "Primary production-Photosynthesis", | t | 295 | "display_name": "Primary production", |
| 261 | "id": "446160f8-ac15-4da8-a39f-79b6c421e396", | 296 | "id": "aca6914d-a728-406d-a5b9-dd9593c21e4e", | ||
| 262 | "name": "Primary production-Photosynthesis", | 297 | "name": "Primary production", | ||
| 263 | "state": "active", | 298 | "state": "active", | ||
| 264 | "vocabulary_id": null | 299 | "vocabulary_id": null | ||
| 265 | }, | 300 | }, | ||
| 266 | { | 301 | { | ||
| 267 | "display_name": "Single species", | 302 | "display_name": "Single species", | ||
| 268 | "id": "88de69be-3bdd-4cf8-b6a1-386d72c5888d", | 303 | "id": "88de69be-3bdd-4cf8-b6a1-386d72c5888d", | ||
| 269 | "name": "Single species", | 304 | "name": "Single species", | ||
| 270 | "state": "active", | 305 | "state": "active", | ||
| 271 | "vocabulary_id": null | 306 | "vocabulary_id": null | ||
| 272 | }, | 307 | }, | ||
| 273 | { | 308 | { | ||
| 274 | "display_name": "Temperate", | 309 | "display_name": "Temperate", | ||
| 275 | "id": "31aaeb0c-a4a5-4a8e-9c90-be1eff0cac91", | 310 | "id": "31aaeb0c-a4a5-4a8e-9c90-be1eff0cac91", | ||
| 276 | "name": "Temperate", | 311 | "name": "Temperate", | ||
| 277 | "state": "active", | 312 | "state": "active", | ||
| 278 | "vocabulary_id": null | 313 | "vocabulary_id": null | ||
| 279 | }, | 314 | }, | ||
| 280 | { | 315 | { | ||
| 281 | "display_name": "Temperature", | 316 | "display_name": "Temperature", | ||
| 282 | "id": "8ffcba75-112d-48f4-b013-882017189fff", | 317 | "id": "8ffcba75-112d-48f4-b013-882017189fff", | ||
| 283 | "name": "Temperature", | 318 | "name": "Temperature", | ||
| 284 | "state": "active", | 319 | "state": "active", | ||
| 285 | "vocabulary_id": null | 320 | "vocabulary_id": null | ||
| 286 | } | 321 | } | ||
| 287 | ], | 322 | ], | ||
| 288 | "title": "Seawater carbonate chemistry and photophysiology and | 323 | "title": "Seawater carbonate chemistry and photophysiology and | ||
| 289 | hemolytic activity of the dinoflagellate Akashiwo sanguinea", | 324 | hemolytic activity of the dinoflagellate Akashiwo sanguinea", | ||
| 290 | "type": "vdataset", | 325 | "type": "vdataset", | ||
| 291 | "url": "https://doi.org/10.1594/PANGAEA.889140" | 326 | "url": "https://doi.org/10.1594/PANGAEA.889140" | ||
| 292 | } | 327 | } |